DE2003659A1 - Power converter with thyristor valves - Google Patents

Description

Power converter with thyristor valves The invention relates to a power converter with thyristor valves, which are controlled by a control unit that is operated via transmission organs Gives control impulses to the various thyristor valves.

When controlling a converter, the control pulses are on the various valves with a certain control angle in relation to the commutation voltages of the valves transferred or more precisely, in proportion to the time at which the commutation voltage of the valve in question becomes positive. Under normal operating conditions So a valve has positive anode voltage in relation to the cathode when the Control electrode of the valve a control pulse is generated. These two conditions are necessary for the valve to ignite. In the event of malfunctions, e.g. due to overvoltages, cause oscillations in the commutation voltage, it can happen that the valve has negative anode voltage at the moment when its control electrode gets a control pulse, or that there is negative anode voltage receives, while the control electrode still holds the control pulse.

With mercury valves this is pretty insignificant, with thyristor valves on the other hand, the combination of negative anode voltage and positive control current have serious consequences for the thyristors of the valve as it can cause a substantial part of the control current from the expensive electrode to the negative Anode can flow. Due to the high voltage drop between the control electrode and the anode the power of this leakage current will be quite high, maybe several hundred watts, since it also occurs within a very small area, so there is a great risk that the thyristor will be destroyed. Part of the thyristor damage seems to be explained by this fact.

It is obvious to counter the above risks by doing this to ensure that one influences the control unit itself, but unfortunately it is both awkward as well as difficult to get precise information about the valve voltage to be transmitted to the control unit which is at ground potential.

According to the invention, in the transmission organs for the control pulses Switching organs influenced by voltage-sensing organs are arranged in such a way that a Such switching element for each valve is only conductive when the voltage is above the Anode-cathode of the valve is positive. If, on the other hand, this voltage becomes zero or negative, the switching element is interrupted.

Both the switching elements and the voltage-indicating Organs are arranged on valve potential, which is a great advantage in terms of Speed and accuracy of protection is.

Apart from the fact that the valves against the above-mentioned unfavorable operating conditions are protected, a further development of the invention leads to additional advantages.

To control the valves in a converter, you can choose between Select short and long control pulses, with long control pulses of essentially the same duration as the on-intervals of the valves are meant. Short control pulses, i.e. control pulses with a duration of up to a few electrical ones Degrees, result in a low mean-effect taxation system. A short impulse with A suitable energy content ensures the ignition of the valve, after which the valve becomes conductive remains as long as its anode voltage is positive.

The control pulses are short under normal operating conditions therefore completely sufficient and therefore preferable. On the other hand, interference can occur in the form of voltage oscillations lead to the mode voltage during the normal lead interval happens to be negative, causing the valve to extinguish prematurely can. With short control impulses it is not possible to achieve within the desired Lead interval to achieve reignition.

When: 'Starting a converter with several connected in series Valve groups, e.g. a two-way bridge circuit, are the control pulses for the various Groups out of phase in relation to each other, which is why the start of one Converter is only possible if the control pulses for the various groups overlap each other, i.e. you have to have long or repeated control impulses.

The same case occurs when the load and therefore the mean of direct current is so low that it has the character of short, of currentless Intermittent pulses received. However, this increases the control energy consumption much larger than with short control pulses and especially with thyristor valves with many thyristors connected in series, which should all ignite at the same time, this is disadvantageous. Another important factor is that nowadays one often especially with thyristor valves, a control pulse transmission in the form of light pulse transmission used. You have to use lighting fixtures with a limited burning time, so that their service life becomes disproportionately short with long control pulses.

In order to avoid this disadvantage, the control device itself is according to A further development of the invention is carried out in such a way that it lasts for a long time algibl, while ilas chaltorgan takes the form of a UNi) link in the control impulse transmission with two inputs, to which partly the control unit and partly the voltage-sensing device Organ are connected in this way the long control impulses become so long conveyed on, how the voltage across the valve is positive. When the valve fires, the voltage goes up above it zero, which means that the expensive pulse, which is now superfluous, is switched off will. In addition, as before, it is ensured that the control pulse is not given when the voltage across the valve is negative.

The invention is described in more detail below with reference to the drawing, in this show Pig. 1, purely schematically, a conventional power converter and 2-4 various exemplary embodiments of a control system according to the invention.

Fig. 1 shows a converter, which consists of a valve bridge with valves 1-, a converter transformer 7, AC connections 3, DC connections 9 and a vteuergerät 10 consists, which via its output terminals 11-16 control pulses to the various valves.

In Fig. 2 one of the valves in Fig. 1, e.g. valve 1, is shown in more detail, which consists of several series-connected thyristors 101 to 104, their number corresponds to the noticeable voltage of the valve. The thyristors are capacitive, resistive Voltage divider elements 111 to 114 connected in parallel, which are shown in more detail in FIG are shown. The thyristors are connected to terminal 1 on control unit 10 in Fig. 1 controlled by the control electrodes on each of a secondary winding 21 to 24 of a :; expensive impu iotranslormators are incurred, the pr-imirwicklllng 2 () Utt r one Contact 33 of relay 31 is connected to terminal 11 is.

The relay 31 is via the valve 1 and a diode 32 from a voltage divider 3 controlled, whereby the relay is switched on and contact 33 is closed, as long as the voltage across valve 1 is positive. Is the tension above that Valve, on the other hand, zero or negative, contact 33 is open, eB cannot receive a control pulse from the control device 10 to the TransformatoTs winding 20 are conveyed. on this In this way, the combination of negative anode voltage / positive control current can be used always avoid the valve. The relay 31, 33 is to be regarded as a symbol. In practice, an electronic switching element will usually be used, e.g. a transistor that is significantly faster and safer. The control pulse transformers can also be used for example, has been exchanged for a light pulse transmission as in Fig. 3.

Fig. 3 shows another embodiment of the principle according to the invention, in which each thyristor is protected for itself.

This has the advantage that the individual thyristor is also in the case protected where a disturbance in the voltage distribution across the valve leads to that one or more thyristors with negative anode voltage fail, although the Total voltage across the valve is positive.

FIG. 3 shows one of the thyristors 101 in valve 1 in FIG. 1 connected in parallel with its part of the voltage divider 111, consisting of a Witler stand in parallel with a second resistance and in series Geseilaltat niit; two capacitors.

The output 11 on the control unit 10 in Fig. 1 is here as a light transmitter e.g., a light emitting diode which controls a photodiode 35. The control power is taken from a special voltage divider 111 'from an energy store consists in the form of a capacitor 38. This one will have a resistor and a Diode fed, which means that the capacitor is always positive on its upper half Polarity is charged. The voltage across your capacitor is measured by means of a Zener diode 31 limited.

The control energy stored in the capacitor i is transmitted via the photodiode 35 and an AND gate 33 transferred to the thyristor 101, the input side of the AND gate partly on the capacitor: and partly on the output of a threshold value generator 34 is connected, which has the same character as the relay 31 in Fig. 2 and the polarity of the voltage across the lower capacitor 99 in voltage divider 111 and the voltage across the thyristor 101. This achieves that the thyristor 1ù1 can only receive control current from the voltage divider 111 'if its anode voltage is positive. Ausseruen: you can see that the whole .hutz arrangement on the potential of the thyristor is arranged so that a transmission of signals to ground potential is not required.

FIG. 4 shows another embodiment of the JQ 'principle according to FIG. 2.

The reference numbers correspond to those in Fig. X (uni). The valves 1 1-1 @ are received from control unit 10 via terminal 11 and a switching element controlled, which is designed as an AND gate 33, the second input of the AND gate 33 is connected to the threshold value generator 34, which the valve voltage across the voltage divider 30 is sampled. One thinks here of the case that the control pulse device 10 long control pulses with the same duration as the desired control interval of the Valve releases. If the anode voltage across the valve is negative, no signal is received from the threshold value generator 34, so that no control pulse from 11 through the AND gate 33 is passed to the control pulse distributor 20.

If, on the other hand, the anode voltage of the valve is positive, the control pulse is applied of 11 passed through the AND gate, so that the valve ignites. When this happens the voltage across the valve becomes essentially zero and the signal from the threshold value generator 34 is omitted. The control pulse from 33 thus stops when the thyristors have received the necessary control energy.

If the valve goes out prematurely for any reason, the The anode voltage is positive again, as a result of which the threshold value generator 34 gives a signal, so that a new control pulse is given via element 33. Such a cease to exist can be due to disturbances in the form of stress oscillations, but is otherwise normal when (; type of converter and at low load, when the track power of the converter has the form of direct current impulses, the e voii stromLoen intervals to be interrupted.

In Fig. 1 three release switches 17, 15, 19 are shown, of which 19 is intended for bypassing the converter, while 17 and 18 for disconnecting of the converter from the DC terminals 9 are provided. With thyristor converters it is now considered practical to use the power converter working valves as to use so-called bypass valves when switching off the converter while in the case of converters with mercury valves, it is usually always parallel to the switch 19 uses a special bypass valve. The process of switching off the converter in Fig. 1 it is as follows: First, two valves connected in series ignite, e.g. 1 and 4.

Then switch 19 is closed, then switches 17 and 18 are opened. The converter is switched on again in the opposite direction, i.e. the switches 17 and 18 are closed, then switch 19 is opened. Received at the same time e.g. valves 1 and 4 ignition pulse. The ignition of the valves for bypass operation happens by the control device 10 with a permanent control signal on the outputs is set at the front of two opposing valves, e.g. outputs 11 and 14 of valves 1 and 4. When the valves for bypass operation are ignited when the Converter after a bypass circuit, one must take into account that the two valves together just about the arc voltage over the opening one Switch 19 have, it being possible for this voltage to be insufficient to achieve a required Signal from the threshold value generator 34 to the second input of the element 33 zuzuführszn.

It is therefore uncertain whether a signal of 33 will be obtained in this case. Instead, it is suggested to use a special control circuit To arrange bypass operation, as indicated in Fig. 4 is indicated. This circle includes a second AND gate 36, the output of which is an unstable trigger circuit or Oscillator 37 controls which when it receives an input signal, e.g. a control signal in the form of a series of short pulses to the control signal distributor 20 gil Das AND gate 36 has two inputs. One is connected to its own control output 11 of the Valve connected to the control unit 10 in Fig.1, while the second at the output 14 of the opposite valve 4 connected in the same phase as in FIG is. In a similar way, the control circuit of the valve 4 with an AND gate is corresponding 36, which is connected to the terminals 11 and 14 of the control unit 10.

In both valves 1 and 4, the AND gate 30 is supplied with control pulses fed by the two valves. In normal operation, these control pulses have a duration from about 1200 and 1800 are out of phase, so they never overlap each other.

In the case of bypass operation, on the other hand, the control pulses are permanent, eo that the AND gates 36 for both valves receive double input signals, whereby the flip-flop 37 is started.

It can also be seen that if valves 1 and 4 during the Byway operation should expire, e.g. for reasons similar to those already described above, the whole DC voltage would occur across the poles 9 across the valves, whereby the threshold value transmitter 34 sends a signal to the element 33 so that the valves 1 and 4 both receive a control signal from both gates 33 and 36.

This is how the bypass operation is started and maintained secured.

Claims (7)

Patent claims: Power converter with thyristor valves controlled by a control unit be, the control pulses to the various thyristor valves via transmission organs there, characterized in that for each thyristor valve a voltage-sensing Organ for sensing the voltage across the valve is present, which the transmission organs influenced in such a way that the aforementioned control pulses are only transmitted when the voltage across the anode-cathode of the valve is positive. 2. Converter according to claim 1, characterized in that the Transmission organs contain a switching organ that is used by the voltage-sensing organ is influenced in such a way that the switching element is only conductive when the said valve voltage is positive. 3. Converter according to claim 2, characterized in that both the voltage sensing element and the switching element are arranged at the same potential are like the corresponding thyristor valve. 4. Converter according to claim 2, wherein each thyristor valve from consists of a number of thyristors connected in series, characterized in that that each thyristor has its own voltage sensing element and its own Switching element for the control pulse transmission is provided by the voltage-sensing Organ is controlled, 5. Converter according to claim 2, wherein the different Thyristor valves by control pulses of the same length as the desired control interval of the valve are controlled by the control unit, characterized in that the Switching element consists of an AND element with two inputs, one input connected to the control pulse device and the other to the voltage sensing organ is. 6. Power converter according to claim 2, wherein at least some of the thyristor valves are arranged so that they act as bypass valves for the converter, thereby characterized in that the control pulses for the bypass operation of the corresponding Valves are connected via another switching organ that is parallel to the first switching organ is arranged. 7. Converter according to claim 6, characterized in that the second switching element consists of a second AND element with two inputs, which the control pulses for the two thyristor valves that work as bypass valves are fed. Blank page